Aerial launch and/or recovery for unmanned aircraft with submersible devices, and associated systems and methods

ABSTRACT

Aerial launch and/or recovery for unmanned aircraft, and associated systems and methods. A representative unmanned aerial vehicle (UAV) comprises an airframe, a plurality of rotors, and a capture line. The rotors are coupled to the airframe and configured to support the UAV in hover. The capture line is carried by the UAV and is operatively coupled to an immersible anchor. The immersible anchor is configured to be immersed within a body of water during a capture operation involving the capture line.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application arises from a division of U.S. patent application Ser.No. 15/269,597, filed Sep. 19, 2016, which claims priority to U.S.Provisional Patent Application No. 62/236,824, filed Oct. 2, 2015, andU.S. Provisional Patent Application No. 62/311,773, filed Mar. 22, 2016.The entireties of U.S. patent application Ser. No. 15/269,597, U.S.Provisional Patent Application No. 62/236,824, and U.S. ProvisionalPatent Application No. 62/311,773 are hereby incorporated by referenceherein.

TECHNICAL FIELD

The present technology is directed generally to aerial launch and/orrecovery for unmanned aircraft, and associated systems and methods.

BACKGROUND

Aircraft require varying degrees of support equipment and systems forlaunch and recovery. Conventionally, aircraft take off from and land onrunways, usually located at airports that provide parking, fuel,hangars, air and ground traffic control, maintenance services, andterminals for passengers, baggage, and freight. Unmanned aircraft,including drones, unmanned aerial vehicles (UAVs), unmanned aircraftsystems (UAS) and robotic aircraft, present unique challenges andopportunities for mechanisms and methods that enable the safe initiationof flight (takeoff or launch) and safe capture, recovery, and return ofthe aircraft. For example, some existing unmanned aircraft are launchedusing catapults, and captured using wing-mounted hooks that engage witha suspended capture line.

While the foregoing techniques, particularly techniques includingcatapult launch and suspended-line capture, have proven successful,there remains a need for systems with improved size, weight, and costcharacteristics.

BRIEF DESCRIPTION OF THE DRAWINGS

Unless otherwise noted, the Figures may not be drawn to scale, forpurposes of illustration and/or clarity.

FIG. 1 is partially schematic illustration of a system that includes afirst aircraft configured to capture a second aircraft, in accordancewith an embodiment of the present technology.

FIG. 2 is a partially schematic illustration of a representative firstaircraft carrying a second aircraft.

FIG. 3 is a partially schematic illustration of a process for deployinga first aircraft, launching a second aircraft carried by the firstaircraft, and landing the first aircraft, in accordance with anembodiment of the present technology.

FIG. 4A is a partially schematic illustration of a first aircraftoperating in an urban environment with obstructions that includebuildings, in accordance with an embodiment of the present technology.

FIG. 4B is an enlarged illustration of a sensing pod and camera carriedby the first aircraft shown in FIG. 4A.

FIG. 5A is a partially schematic illustration of multiple first aircraftoperating to position a capture line in a generally vertical orientationfor capturing a second aircraft, in accordance with an embodiment of thepresent technology.

FIG. 5B is a partially schematic illustration of multiple first aircraftoperating to position a capture line in a generally horizontalorientation for capturing a second aircraft, in accordance with anotherembodiment of the present technology.

FIG. 6 is a partially schematic illustration of multiple first aircraftoperating to support a net for capturing a second aircraft, inaccordance with another embodiment of the present technology.

FIG. 7 is a partially schematic illustration of a first aircraft thatreceives power from a ground-based power source, alone or in combinationwith another aircraft, in accordance with embodiments of the presenttechnology.

FIG. 8 is a partially schematic illustration of a first aircraftpositioned above obstructions to capture a second aircraft, inaccordance with embodiments of the present technology.

FIG. 9 is a partially schematic illustration of a first aircraft thatreceives power from a ground-based power source via a wireless link, inaccordance with another embodiment of the present technology.

FIG. 10 illustrates controllers configured to control first and/orsecond aircraft, in accordance with embodiments of the presenttechnology.

FIG. 11 is a partially schematic illustration of a first aircraft havinga launch fixture for carrying a second aircraft, in accordance with anembodiment of the present technology.

FIG. 12 is partially schematic illustration of a first aircraft having alaunch fixture for carrying a second aircraft, in accordance withanother embodiment of the present technology.

FIG. 13 illustrates a representative first aircraft carrying arepresentative second aircraft during operations in accordance with anembodiment of the present technology.

FIG. 14A is a partially schematic illustration of a first aircraftconfigured to operate in a marine environment, in accordance with anembodiment of the present technology.

FIGS. 14B-14D are a partially schematic illustrations of a firstaircraft configured to operate in a marine environment, in accordancewith another embodiment of the present technology.

DETAILED DESCRIPTION

The present disclosure describes systems and methods for launchingand/or recovering aircraft, in particular, unmanned aircraft. Manyspecific details of certain embodiments of the disclosure are set forthin the following description and FIGS. 1-14D to provide a thoroughunderstanding of these embodiments. Well-known structures, systems, andmethods that are often associated with such embodiments, but that mayunnecessarily obscure some significant aspects of the disclosure, arenot set forth in the following description for purposes of clarity.Moreover, although the following disclosure sets forth severalembodiments of the technology, several other embodiments of thetechnology can have different configurations and/or different componentsthan those described in this section. As such, the technology mayinclude other embodiments with additional elements, and/or withoutseveral of the elements described below with reference to FIGS. 1-14D.

Many embodiments of the technology described below may take the form ofcomputer- or controller-executable instructions, including routinesexecuted by a programmable computer or controller. Those skilled in therelevant art will appreciate that the technology can be practiced oncomputer/controller systems other than those shown and described below.The technology can be embodied in a special-purpose computer, controlleror data processor that is specifically programmed, configured orconstructed to perform one or more of the computer-executableinstructions described below. Accordingly, the terms “computer” and“controller” as generally used herein refer to any data processor andcan include Internet appliances and hand-held devices (includingpalm-top computers, wearable computers, cellular or mobile phones,multi-processor systems, processor-based or programmable consumerelectronics, network computers, mini computers and the like).Information handled by these computers can be presented at any suitabledisplay medium, including a CRT display or LCD.

The technology can also be practiced in distributed environments, wheretasks or modules are performed by remote processing devices that arelinked through a communications network. In a distributed computingenvironment, program modules or subroutines may be located in local andremote memory storage devices. Aspects of the technology described belowmay be stored or distributed on computer-readable media, includingmagnetic or optically readable or removable computer disks, as well asdistributed electronically over networks. Data structures andtransmissions of data particular to aspects of the technology are alsoencompassed within the scope of the embodiments of the technology.

FIG. 1 is a partially schematic illustration of a system 100 thatincludes a first aircraft 101 and a second aircraft 120. The firstaircraft 101 can be configured to launch, capture, or both launch andcapture the second aircraft 120. Accordingly, the first aircraft 101 maybe referred to herein as a carrier or support aircraft, and the secondaircraft 120 may be referred to herein as a carried or target aircraft.The carrier aircraft can conduct a carrying function before launchand/or after capture, and the carried aircraft can be carried beforelaunch and/or after capture. In particular embodiments, the system 100can be configured to operate in an environment 140 having obstructions141 that make conventional techniques for launching and/or capturing thesecond aircraft 120 difficult. Further details of representative firstaircraft 101, second aircraft 120, and the environments in which theyoperate are described below.

With continued reference to FIG. 1 , the first aircraft 101 can beconfigured for vertical takeoff and landing (VTOL), and hover, to allowfor operation in constrained areas. Accordingly, the first aircraft 101can include an airframe 102 and multiple rotors 103 (e.g., in aquad-rotor configuration) powered by an on-board power source 104. Thefirst aircraft 101 can include a first capture device 105, for example,a flexible capture line 106 that hangs down from the first aircraft 101in a position suitable for engaging with the second aircraft 120 duringa capture operation.

In a particular embodiment, the second aircraft 120 can have afixed-wing configuration, with a fuselage 121 carried by fixed wings122. The second aircraft 120 is propelled by a propulsion system 128,e.g., an on-board propulsion system. The propulsion system 128 caninclude one or more pusher propellers (one is shown in FIG. 2 ) ortractor propellers, powered by an internal combustion engine, electricmotor, battery, and/or other suitable device. The second aircraft 120can include a second capture device 123 positioned to engage with thefirst capture device 105 carried by the first aircraft 101. Inparticular embodiments, the second capture device 123 includes one ormore wing tip hooks 124. When one of the wings 122 strikes the captureline 106, the corresponding wing tip hook or hooks 124 releasably engagewith the capture line 106, causing the captured second aircraft 120 todangle from the capture line 106. The first aircraft 101 then guides thecapture line 106 and the captured second aircraft 120 in a controlleddescent to the ground. Further details of representative capture devicesand techniques are described in U.S. Pat. Nos. 6,264,140 and 7,059,564,both assigned to the assignee of the present application, and bothincorporated herein by reference.

In an embodiment shown in FIG. 1 , the system 100 includes a downlineapparatus 170 to which the capture line 106 is attached. The downlineapparatus 170 can include an anchor and/or shock absorbing elements thatcushion the impact of the second aircraft 120 with the capture line 106.

In operation, the first aircraft 101 flies upwardly (e.g., verticallyupwardly) to a position above the local obstructions 141 and a heightsufficient to facilitate capturing the second aircraft 120. As shown inFIG. 1 , the obstructions 141 can include trees 142 (e.g., in a forestor jungle), and the first aircraft 101 can ascend through a relativelysmall opening or clearing 144 in the trees 142. The power source 104,which provides power to the rotors 103 of the first aircraft 101, caninclude an internal combustion engine, a battery, and/or anothersuitable device that is carried aloft with the first aircraft 101. Inother embodiments described later, the first aircraft 101 can receivepower from a ground-based source. In any of these embodiments, the firstaircraft 101 rises to a position indicated by letter A to capture thesecond aircraft 120, and then descends, as indicated by letter B oncethe second aircraft 120 has been captured. Near the ground, the firstaircraft can lower the second aircraft 120 to the ground, autonomously,or under control of a pilot, with or without the assistance of a humanoperator on the ground to manually handle the aircraft as it descendsthe last few feet.

A representative power source 104 for the first aircraft 101 includes arechargeable battery. An advantage of the rechargeable battery, whencompared to other power sources such as an internal combustion engine,is that the battery can eliminate the need for an on-board fuel source(e.g., gasoline, aviation fuel, and/or another fuel) while stillproviding sufficient short-term power for a launch operation and/or arecovery operation.

In particular embodiments, the first aircraft 101 can be configured notonly to capture the second aircraft 120, but also to launch the secondaircraft 120 from an aerial position. FIG. 2 schematically illustratesthe general features of such an arrangement. As shown in FIG. 2 , thefirst aircraft 101 can include a central portion 107 (e.g., a fuselage),and multiple arms 108. The propulsion system 128 can include multiplerotors 103 carried by the corresponding arms 108. The first aircraft 101can also include a launch fixture 190 positioned to securely hold thesecond aircraft 120 during an ascent maneuver. The launch fixture 190 isconfigured to release the second aircraft 120 once aloft (e.g., uponcommand), and permit the first aircraft 101 to land without the secondaircraft 120 attached. In a particular embodiment, the second aircraft120 can include a ScanEagle® UAV, manufactured by Insitu, a subsidiaryof The Boeing Company, and in other embodiments, can include othervehicles.

In operation, the first aircraft 101 lifts the second aircraft 120 asindicated by arrow L, rotates to a suitable orientation as indicated byarrow R and translates to a suitable launch location as indicated byarrow T. Optionally, the first aircraft 101 can rotate again at thelaunch location, e.g., to position the second aircraft 120 facing intothe wind for launch. The propulsion system 128 of the second aircraft120 can be started either before the second aircraft 120 has beenlifted, or after the second aircraft 120 is aloft. Once at the launchlocation, the first aircraft 101 releases the second aircraft 120 forflight, as will be described in further detail later with reference toFIGS. 11-12 . In some embodiments, the second aircraft 120 is releasedat a high enough elevation (and has a suitably high glide slope) that itdrops, gains air speed, and then levels off. In other embodiments, thefirst aircraft 101 has sufficient forward velocity at launch to reduceor eliminate any drop in elevation by the second aircraft 120 as thesecond aircraft 120 is released.

FIG. 3 is a partially schematic illustration of a representative firstaircraft 101 operating from an enclosed space 350. The enclosed space350 can include a building 351 having a restricted opening 352 throughwhich the first aircraft 101 exits in preparation for a launchoperation, and returns after the launch operation is complete. Afterreturning, the same or a different first aircraft 101 can be preparedfor a capture operation, e.g., by charging (or re-charging) on-boardbatteries or other power sources, and connecting to a capture line. Thefirst aircraft 101 can then re-deploy from the enclosed space 350 toconduct a capture operation and again return to the enclosed space 350.The enclosed space 350 can enhance the “stealth” characteristics of theoverall operation by obscuring the ability of others to observe thelaunch and recovery operations. In other embodiments, the enclosed space350 can provide a sheltered area for operations, maintenance, refueling,recharging, inspections, reconfigurations, and/or other suitableelements of flight operations. The enclosed space 350 can include atemporary structure, a permanent structure, a natural protected volumewith a restricted opening (e.g., a cave or overhang), and/or a naturalspace beneath a forest or jungle canopy (which can optionally be clearedand shaped for suitable operation). The enclosed space 350 can includesoft and/or hard materials, for example, cloth, metal, concrete, wood,suitable fasteners and adhesives, and/or other suitable materials.

The first aircraft 101, second aircraft 120, and associated hardware andsystems can be housed in one or more shipping containers 353 fortransport to and from operational locations. The shipping containers 353can also be housed in the enclosed space 350. To date, forwardoperations are provisioned at arbitrary times in the typical timeline ofa forward operation, without the option to selectively pick and procurearbitrary lists of individual parts required for successful, smoothconduct of operations. Such operations can include surveillance andsensing using daylight and infrared cameras attached to the secondaircraft 120. The shipping containers 353 can include standard boxes,for example, molded containers designed for modular (e.g., foldable oreasily disassemble) unmanned aircraft, that can be provisioned witharbitrary selected combinations of components. Accordingly, thecomponent set for a given mission can be standardized, which improvesthe efficiency with which the mission is supported and carried out.

FIG. 4A is a partially schematic illustration of a representative firstaircraft 101 operating in an urban environment 440 that includesobstructions 441 in the form of buildings 445 and/or other typicallyurban structures. The first aircraft 101 can operate in a mannergenerally similar to that described above with reference to FIGS. 1-3and, in a particular embodiment, can include one or more sensors 460 toaid in navigation during launch and/or capture operations. The sensor460 can be housed in a sensing pod 461, a portion of which is shown ingreater detail in FIG. 4B. As shown in FIG. 4B, the sensor 460 caninclude a camera 462, and the sensing pod 461 can be formed from atransparent material that protects the camera 462, while allowing thecamera 462 suitable access to the environment 440. The camera 462 canoperate at visible wavelengths, infrared wavelengths, and/or othersuitable wavelengths, depending upon the particular mission carried outby the first aircraft 101. The sensing pod 461 can be carried by thefirst aircraft 101 in a position that allows for a significant field ofview 463 (shown in FIG. 4A). The camera 462 can be used to perform anyone or combination of functions associated with launching and capturingthe second aircraft. For example, the camera 462 can be used to avoidobstacles as the first aircraft 101 ascends and descends during launchand/or recovery operations. During recovery operations, the camera 462can also be used to gently lower the captured aircraft to the groundwithout damaging it.

As discussed above with reference to FIG. 1 , the system 100 can includea downline apparatus 170 that secures the capture line 106 to the groundduring capture operations. In at least some embodiments, it may not befeasible or practical to secure the capture line to the ground duringcapture operations. In such cases, the system can be configured tosuspend the capture line between multiple first aircraft to providesuitable tension in the line, without relying on a ground-based anchor.For example, referring to FIG. 5A, a representative system 500 a caninclude two first or support aircraft 501 a, 501 b carrying a firstcapture device 505 a between them. In this embodiment, the first capturedevice 505 a includes a generally vertical capture line 506 a, e.g., acapture line that is more vertical than horizontal. The two firstaircraft 501 a, 501 b can be positioned one above the other to align thecapture line 506 a in a generally vertical orientation. A secondaircraft 120, e.g., having a configuration generally similar to thatdescribed above with reference to FIG. 1 , can include a correspondingsecond capture device 523 a that includes wing-tip hooks 524 positionedto engage the capture line 506 a. The two first aircraft 501 a, 501 bcan fly cooperatively to provide the proper tension in the capture line506 a, and to safely bring the second aircraft 120 to the ground aftercapture. In particular embodiments, the coordinated operation of the twofirst aircraft 501 a, 501 b can be autonomous, or partially autonomous,with the first aircraft 501 a, 501 b communicating directly with eachother to perform the capture and landing operation. In still a furtheraspect of this embodiment, a manual override instruction issued by theoperator (e.g., seizing manual control) will be applied to both thefirst aircraft 501 a, 501 b.

FIG. 5B illustrates an arrangement similar to that shown in FIG. 5A, butwith the two first or support aircraft 501 a, 501 b carrying a firstcapture device 505 b that includes a capture line 506 b positioned in agenerally horizontal rather than vertical orientation (e.g., with thecapture line 506 b more horizontal than vertical). This orientation canbe suitable for capturing a second aircraft having a different secondcapture device. For example, as shown in FIG. 5B, a representativesecond aircraft 520 can include a second capture device 523 b that inturn includes an upper hook 525 and a lower hook 526. The hooks 525, 526can be stowed during normal flight and then deployed prior to capture.In particular embodiments, only one of the hooks 525, 526 is deployed,depending upon the position of the second aircraft 520 relative to thecapture line 506 b. In other embodiments, both hooks 525, 526 can bedeployed to provide greater assurance of a successful capture,regardless of whether the second aircraft 520 passes above or below thecapture line 506 b during the capture operation.

In still further embodiments, multiple first aircraft can carry anddeploy capture devices having configurations other than a suspendedcapture line. For example, referring now to FIG. 6 , two first aircraft601 a, 601 b are configured to carry a capture device 605 between them,with the capture device 605 including a net 610. The net 610 can be usedto capture aircraft that may not have the specific capture devicesdescribed above with reference to FIGS. 5A-5B (e.g., wing-tip hooksand/or upper and lower hooks). In one aspect of this embodiment, the net610 may have weights at or near the lower edge to keep the net 610properly oriented. In another embodiment, two additional first aircraft601 c, 601 d (shown in dashed lines) are used to provide support andpositioning for the lower corners of the net 610. In particularembodiments, the second aircraft (not shown in FIG. 6 ) captured via thenet 610 can be specifically configured for such capture operations. Forexample, the second aircraft can have fewer and/or particularly robustprojections that withstand the forces that may be encountered as thesecond aircraft engages with the net 610. In other embodiments, thesecond aircraft and/or the techniques used to capture the secondaircraft with the net 610 can be configured to avoid the need for suchspecific designs. For example, the first aircraft 601 a, 601 b carryingthe net 610 can fly the net in the same direction as the incoming secondaircraft to reduce the forces imparted to the second aircraft as itengages with the net 610.

One aspect of an embodiment of the system described above with referenceto FIG. 1 is that the power source for the first aircraft (e.g., abattery-powered motor, or an internal combustion engine) is carriedon-board the first aircraft. In other embodiments, power can be suppliedto the first aircraft from a ground-based source. For example, referringnow to FIG. 7 , a representative first aircraft 701 a can receive powerfrom a ground-based power source 730, via a power transmission link 731.In a particular aspect of this embodiment, the power transmission link731 can include a power cable 732 a that transmits electrical power to apower receiver 713 carried by the first aircraft 701 a. The powerreceiver 713 can include a connector 711, for example, a quick-releaseelectrical connector, which is coupled to one or more on-boardelectrical motors to drive corresponding rotors 703 of the firstaircraft 701 a. The first aircraft 701 a can carry a capture line 706for capturing a suitably-equipped second aircraft 120 a (FIG. 5A).

In another aspect of an embodiment shown in FIG. 7 , the system caninclude multiple first aircraft shown as two first aircraft 701 a, 701b, e.g., to position the power transmission link 731 in a way thatreduces or eliminates interference with the capture line 706. Forexample, one first aircraft 701 a (shown in solid lines) can carry thecapture line 706 and the power receiver 713, and another first aircraft701 b (shown in dotted lines) can carry a corresponding power cable 732b (also shown in dotted lines) in a position that is offset away fromthe capture line 706. Accordingly, one of the first aircraft can performthe capture operation (and optionally a launch operation) and the othercan provide a support function. The first aircraft 701 b performing thesupport function can have the same configuration as the first aircraft701 a performing the capture function, or the two aircraft can havedifferent configurations. For example, the first aircraft 701 bperforming the support function can have a greater or lesser loadcapacity, depending on whether the loads associated with the power-cablecarrying function are greater or less than the loads associated with thecapture function. The corresponding power cable 732 b can includemultiple segments, for example, one segment between the ground-basedpower source 730 and the first aircraft 701 b, and another between thetwo first aircraft 701 a, 701 b.

Whether or not multiple first aircraft 701 are employed in thearrangement shown in FIG. 7 , the capture line 706 can be attached to adownline apparatus 770 that includes one or more anchors 771. Theanchor(s) 771 can perform different functions. For example, one anchorcan redirect the path of the capture line 706 to another anchor, whichincludes shock absorbing features to cushion the impact of a secondaircraft 120 (FIG. 5A) striking the capture line 706 during a captureoperation.

As discussed above, the capture line 706 can be tensioned via aground-based downline apparatus, or by another aircraft. In stillanother embodiment, shown in FIG. 8 , a representative first aircraft101 can carry a capture line 106 that is tensioned by a hanging mass812, e.g., attached to the capture line 106 at or near its free end.This arrangement can allow the first aircraft 101 to perform a captureoperation while positioned completely above any nearby obstructions 141,without the need for access to the ground (or another first aircraft) toprovide tension in the capture line 106.

FIG. 9 is a partially schematic illustration of a system 900 thatincludes a first aircraft 901 configured to receive power from aground-based source 930 via a wireless link. In a particular aspect ofthis embodiment, the ground-based power source 930 includes a radiationsource 933, e.g., a source of illumination or other electromagneticradiation 934. The first aircraft 901 can include a power receiver 913that in turn includes one or more wireless receiver elements 914positioned to receive energy from the ground-based power source 930. Forexample, the power receiver 913 can include one or more photovoltaiccells 915 that receive the radiation 934, convert the radiation toelectrical current, and provide the electrical current to motors thatdrive the rotors 103 or other propulsion system components.

The first aircraft 901 is shown carrying a capture line 906 that isconnected to a downline apparatus 970. The downline apparatus 970 caninclude an anchor 971 (e.g., a pulley) and a tension device 972 (e.g.,an elastic, spring-bearing, and/or other shock absorbing device) forhandling and/or controlling the motion of the capture line 906 and thecaptured second aircraft (not shown in FIG. 9 ).

One feature of embodiments of the system described above with referenceto FIG. 9 is that the wireless system for transmitting energy from theground to the first aircraft can simplify the flight operations of thefirst aircraft, for example, by reducing limitations imposed by thepower transmission line 731 discussed above with reference to FIG. 7 .Conversely, using a wired or direct power transmission link of the typedescribed above with reference to FIG. 7 can provide energy moreefficiently than a wireless link and the energy conversion processesassociated therewith.

Referring now to FIG. 10 , in any of the embodiments described above,the systems include one or more controllers 1080 to monitor and directthe operations of the various aircraft. For example, the first aircraft101 can include a first on-board controller 1083, and the secondaircraft 120 can include a second on-board controller 1084. Each ofthese controllers directs the movement of the respective aircraft viasignals directed to the propulsion systems, moveable aerodynamicsurfaces, and/or other aircraft components. In some embodiments, theoperation of the first and second aircraft 101, 120 can be completelyautonomous, with each aircraft pre-programmed before operation. In otherembodiments, both aircraft are controlled via a single ground-basedcontroller, and in still a further particular embodiment, each aircraftis controlled by a separate controller. Accordingly, the overallcontroller 1080 can include a first off-board controller 1081 a (e.g., afirst ground station) operated by a first operator 1086 a and incommunication with the first aircraft 101 via a first communication link1085 a. The controller 1080 can further include a second off-boardcontroller 1081 b (e.g., a second ground station), operated by a secondoperator 1086 b, and in communication with second aircraft 120 via asecond communication link 1085 b. The first and second operators 1086 a,1086 b can communicate with each other, e.g., orally by being co-locatednext to or near each other, or via phone, two-way radio, or any othersuitable longer range communication device. The off-board controllerscan perform any of a wide variety of diagnostic and informational tasks,in addition to providing control instructions to the first and secondaircraft. For example, the controllers can provide an automated orpartially automated checklist and countdown procedure for an aircraftlaunch and/or recovery.

FIGS. 11-13 illustrate first and second aircraft configured inaccordance with particular embodiments of the present technology.Beginning with FIG. 11 , a representative first aircraft 101 can includea launch fixture 1190 releasably attached to an attachment fixture 1127carried by the second aircraft 120. In a particular aspect of thisembodiment, the attachment fixture 1127 fits into a corresponding slot1192 of the launch fixture 1190, and the launch fixture 1190 furtherincludes a release mechanism 1191. The release mechanism 1191 canobstruct or prevent motion of the attachment fixture 1127 until launch,at which point, the release mechanism 1191 can be moved to a releaseposition (as indicated in dotted lines in FIG. 11 ), allowing the secondaircraft 120 to slide downwardly and away from the first aircraft 101via the slot 1192.

In an embodiment shown in FIG. 12 , the first aircraft 101 includes alaunch fixture 1290 configured in accordance with another embodiment ofthe present technology. The launch fixture 1290 can include a pivot pin1295 that releasably engages with a corresponding attachment fixture1227 carried by the second aircraft 120. For example, the pivot pin 1295can translate into or out of the plane of FIG. 12 to disengage from theattachment fixture 1227. The first aircraft 101 can further include apositioning apparatus 1293 having a plunger 1294 that, when activated,forces the nose of the second aircraft 120 downwardly. During arepresentative launch operation, the pivot pin 1295 and plunger 1294 areactuated in sequence to both release the second aircraft 120 and forcethe nose of the second aircraft 120 downwardly so that it (a) picks upsufficient air speed to fly on its own, and (b) reduces the likelihoodfor interference with the first aircraft 101. For example, in oneembodiment, the pin 1295 is disengaged first, and, upon an indicationthat the pin 1295 has been successfully disengaged, the plunger 1294then operates to push down the nose of the second aircraft 120. Inanother embodiment, the plunger 1294 is actuated first to place thesecond aircraft 120 in a downward-facing orientation, before the pin1295 is released. In any of these embodiments, the second aircraft 120can be initially carried in a horizontal attitude, for example, as thefirst aircraft 101 flies horizontally to a launch site. One advantage ofthis arrangement is that it is expected to reduce the drag on both thesecond aircraft 120 and the first aircraft 101 during this flight.

FIG. 13 illustrates further details of a representative system 1300including the first aircraft 101 and second aircraft 120 shown in FIG. 2. The first aircraft 101 can include an airframe 102 formed by a centralportion 107 and multiple, outwardly extending arms 108. Each arm 108 cansupport one or more rotors 103. For example, in an embodiment shown inFIG. 13 , each of the four arms supports two counter-rotating rotors103. The first aircraft 101 can further include multiple landing gear1309 and a launch fixture 190 that are configured to allow the firstaircraft 101 to support the second aircraft 120 while the first aircraft101 is on the ground. In this position, the landing gear 1309 provideenough ground clearance for the second aircraft 120 to allow a propeller1329 of the second aircraft 120 to operate. In this particularembodiment, the landing gear 1309 can include four elements, eachconfigured to support one of the four arms 108. One or more of thelanding gear elements (e.g., two) can be further configured to haveflat, vertically extending surfaces that operate as vertical stabilizers1316 to enhance the in-flight stability of the first aircraft 1301.

FIGS. 14A-14D illustrate systems and methods for capturing unmannedaerial vehicles in a marine or other water-based environment, inaccordance with further embodiments of the present technology. Forpurposes of illustration, capture operations are shown in FIGS. 14A-14D.In other embodiments, the same or different aircraft can be used tolaunch the UAVs, for example, in accordance with the techniquesdescribed above.

Beginning with FIG. 14A, a representative system 1400 a can include afirst aircraft 101 configured to capture and/or launch a second aircraft120. Accordingly, the first aircraft 101 can carry a capture line 106that is in turn connected to a downline apparatus 1470. The downlineapparatus 1470 can be carried at least in part by a water-borne vessel1477 (e.g., a boat, ship, barge, and/or other suitable platform), andcan include a drag cable 1473 connected to the capture line 106 with aconnecting device 1474 (e.g., a slip ring or other suitable device). Thedrag cable 1473 is connected to a drag cable deployment device 1475(e.g., a winch) that can be used to reel the drag cable 1473 in and out.The drag cable 1473 can be connected at its opposite end to animmersible anchor, e.g., a sea anchor 1471 and (optionally), anadditional mass 1476, which keeps the drag cable 1473 in a stableorientation relative to the capture line 106 and the vessel 1477.

In one mode of operation, the second aircraft 120 flies into the captureline 106, engaging wing tip hooks 124 with the capture line 106 in amanner generally similar to that described above. The drag cabledeployment device 1475 can then be used to reel in the capture line 106,the sea anchor 1471, and the mass 1476, before or after the firstaircraft 101 descends to the vessel 1477 to deposit the captured secondaircraft 120.

A system 1400 b in accordance with another embodiment (shown in FIGS.14B-14D) includes a first aircraft 101 that operates without beingattached to the vessel 1477 via the drag cable 1473. Instead, the firstaircraft 101, with the capture line 106, sea anchor 1471 and optionaladditional mass 1476, can be delivered by the vessel 1477 to aparticular location, and released. After being released, the firstaircraft 101 captures the second aircraft 120 in a manner generallysimilar to that discussed above. The first aircraft 101 then flies thesecond aircraft 120 to the vessel 1477. For example, as shown in FIG.14C, the first aircraft 101 can lift the second aircraft 120, the seaanchor 1471 and the additional mass 1476 from the water and fly towardthe vessel 1477. At the vessel 1477, as shown in FIG. 14D, the firstaircraft 101 can lower the second aircraft 120 to be secured at thevessel 1477, and can then itself land on the vessel 1477.

One aspect of several of the embodiments described above with referenceto FIGS. 1-14D is that the disclosed unmanned aerial vehicle systems caninclude a first, unmanned aircraft that launches, recovers, or bothlaunches and recovers a second, unmanned aircraft. One advantage of thisfeature is that it allows the second aircraft to be deployed from andreturned to sites with very limited access. Accordingly, such systemscan operate in areas that are typically inaccessible to second unmannedaircraft having a fixed wing configuration. Because such aircrafttypically have a longer endurance than multi-rotor unmanned aerialvehicles, the ability to deploy and recover such aircraft from moreremote and inaccessible locations can significantly increase the overallrange and endurance of the system.

Another feature of at least some of the foregoing embodiments is thatthe configurations of the first and second aircraft can differsignificantly, in a manner that corresponds with the different missionscarried out by the aircraft. For example, the first aircraft can beconfigured to have a relatively short endurance, and can be configuredto take off and land vertically, thus allowing it to operate in confinedspaces. The second aircraft, by contrast, can be configured to carry outlong-range missions, and can further be configured to be launched and/orcaptured by the first aircraft.

From the foregoing, it will be appreciated that specific embodiments ofthe present technology have been described herein for purposes ofillustration, but various modifications may be made without deviatingfrom the disclosed technology. For example, the first and secondaircraft described above can have configurations other than thoseexpressly shown in the figures. In general, the first aircraft can havea VTOL configuration, and the second aircraft can have a different(e.g., fixed wing) configuration. However, in other embodiments, eitheror both the first and second aircraft can have other configurations.

As discussed above, the first aircraft can carry out a launch functiononly, a capture function only, or both a launch and capture function. Inparticular embodiments, the same aircraft can carry out both launch andcapture functions. For example, the first aircraft shown in FIGS. 14A-Dcan be configured for capture operations (as shown), or launchoperations, or both. In other embodiments, different aircraft (e.g.,having the same or different configurations) can carry out the launchand capture functions. For example, in some embodiments, one aircraftlaunches the second aircraft and, while it is being recharged orotherwise prepared for another launch, a different aircraft performs thecapture function.

The UAVs described above (e.g., the second aircraft 120) are generallysmall to medium in size. For example, a representative second aircrafthas a takeoff gross weight of between 40 and 55 lbs. In otherembodiments, the second aircraft can have other suitable weights.

Several of the embodiments described above were described in the contextof obstructed environments, for example, forested environments, crowdedurban environments, and/or other such environments. In otherembodiments, the same or similar systems can be used in environmentsthat do not have such obstructions.

The first aircraft described above are illustrated as multi-rotoraircraft with four or eight rotors. In other embodiments, the firstaircraft can have other rotor configurations (e.g., six rotors). In anyof these embodiments, the power sources used to power the first aircraftcan include batteries, internal combustion engines, turbines, fuelcells, and/or other suitable sources.

In a particular embodiment for which the first aircraft receives powerfrom a ground-based source (for example, a power cable), the functionprovided by the power cable can be combined with the function providedby the capture line. For example, the same cable can both carry power tothe first aircraft from the ground, and can be used to capture thesecond aircraft. In such embodiments, the cable is thick enough to carrythe required electrical current to the first aircraft, thin enough toengage with the capture device carried by the second aircraft, androbust enough to withstand multiple impacts with the second capturedevice.

In general, the capture line is not carried aloft during a typicallaunch operation. In other embodiments, the capture line can be liftedalong with the second aircraft during a launch operation. Accordingly,if the second aircraft undergoes a malfunction shortly after launch, therecovery line can be used to retrieve the second aircraft. Such anarrangement may be suitable if the second aircraft can be launched fromthe first aircraft while the first aircraft hovers, rather than whilethe first aircraft is engaged in forward flight. In still furtherembodiments, the first aircraft can carry the recovery line entirely onboard, without the recovery line being connected to the ground. Therecovery line can accordingly be stowed on board the first aircraft anddeployed only when needed for recovery.

When multiple aircraft are deployed to carry out and/or support a launchand/or capture operation (e.g., as discussed above with reference toFIGS. 5A-7 ), any of the aircraft can be programmed with instructions tooperate in concert with each other, in a master/slave arrangement, asdiscussed above with reference to FIG. 5A, or in another suitablearrangement.

Certain aspects of the technology described in the context of particularembodiments may be combined or eliminated in other embodiments. Forexample, the launch and recovery functions can be integrated into asingle aircraft or divided among multiple aircraft. The sensorsdescribed in the context of an embodiment shown in FIGS. 4A-B can beincluded in other embodiments as well. Further, while advantagesassociated with certain embodiments of the technology have beendescribed in the context of those embodiments, other embodiments mayalso exhibit said advantages, and not all embodiments need necessarilyexhibit such advantages to follow within the scope of the presenttechnology. Accordingly, the present disclosure and associatedtechnology can encompass other embodiments not expressly described orshown herein.

To the extent any of the materials incorporated herein by referenceconflict with the present disclosure, the present disclosure controls.

What is claimed is:
 1. An unmanned aerial vehicle (UAV) capture system,the system comprising: a first UAV including: an airframe, and aplurality of rotors coupled to the airframe and configured to supportthe first UAV in hover; a drag cable; an immersible anchor configured tobe immersed within a body of water; and a capture line carried by thefirst UAV, wherein a first end of the capture line is coupled to theairframe, and wherein a second end of the capture line opposite thefirst end is coupled to the drag cable, the drag cable supporting theimmersible anchor for capture of a second UAV in flight with the captureline.
 2. The UAV capture system of claim 1, wherein the drag cableextends between the immersible anchor and a waterborne vessel.
 3. TheUAV capture system of claim 2, wherein the drag cable is operativelycoupled to a winch, and wherein the winch is coupled to the waterbornevessel and configured to reel the drag cable in and out relative to thewaterborne vessel.
 4. The UAV capture system of claim 3, wherein a firstend of the drag cable is coupled to the winch, and wherein a second endof the drag cable opposite the first end of the drag cable is coupled tothe immersible anchor.
 5. The UAV capture system of claim 4, wherein thesecond end of the drag cable is further coupled to a weighted mass, theweighted mass configured to maintain the drag cable in a stableorientation relative to the capture line and the waterborne vesselduring the capture of the second UAV.
 6. The UAV system of claim 5,wherein the weighted mass extends from the drag cable at a firstposition of the drag cable and the immersible anchor extends from thedrag cable at a second position of the drag cable different from thefirst position.
 7. The UAV of claim 6, further including a cableextending between the drag cable and the weighted mass.
 8. The UAVcapture system of claim 4, wherein the winch is configured to reel inthe drag cable, the immersible anchor, and the capture line toward thewaterborne vessel when the first UAV carries the second UAV on thecapture line when the second UAV is captured.
 9. The UAV capture systemof claim 1, wherein the second end of the capture line is coupled to thedrag cable via a ring.
 10. The UAV system of claim 1, wherein the dragcable is further coupled to a weighted mass, the weighted massconfigured to maintain the drag cable in a stable orientation relativeto the capture line during the capture of the second UAV.
 11. The UAVsystem of claim 1, wherein the first UAV is configured to capture thesecond UAV via the capture line, and wherein the first UAV is configuredto carry the captured second UAV from a first location at which thecapture occurred to a second location aboard a waterborne vessel.
 12. Amethod, comprising: commencing a flight of a first unmanned aerialvehicle (UAV) of a UAV system, the first UAV including: an airframe; aplurality of rotors coupled to the airframe and configured to supportthe first UAV in hover during the flight of the first UAV; a drag cable;an immersible anchor; and a capture line carried by the first UAV,wherein a first end of the capture line is coupled to the airframe, andwherein a second end of the capture line opposite the first end iscoupled to the drag cable, the drag cable supporting the immersibleanchor; and immersing the immersible anchor within a body of water forcapture of a second UAV in flight with the capture line.
 13. The methodof claim 12, wherein the drag cable extends between the immersibleanchor and a waterborne vessel.
 14. The method of claim 13, wherein thesecond end of the capture line is coupled to the drag cable via a ring.15. The method of claim 13, wherein the drag cable is operativelycoupled to a winch, and wherein the winch is coupled to the waterbornevessel and configured to reel the drag cable in and out relative to thewaterborne vessel.
 16. The method of claim 15, wherein a first end ofthe drag cable is coupled to the winch, and wherein a second end of thedrag cable opposite the first end of the drag cable is coupled to theimmersible anchor.
 17. The method of claim 16, wherein the second end ofthe drag cable is further coupled to a weighted mass, the weighted massmaintaining the drag cable in a stable orientation relative to thecapture line and the waterborne vessel during the capture of the secondUAV.
 18. The method of claim 16, further comprising: capturing thesecond UAV via the capture line of the first UAV; and operating thewinch to reel in the drag cable, the immersible anchor, and the captureline toward the waterborne vessel when the first UAV carries the secondUAV on the capture line when the second UAV is captured.
 19. The methodof claim 12, wherein the drag cable is further coupled to a weightedmass, the weighted mass maintaining the drag cable in a stableorientation relative to the capture line during the capture of thesecond UAV.
 20. The method of claim 12, further comprising: capturingthe second UAV via the capture line of the first UAV; and carrying thesecond UAV when captured from a first location at which the second UAVbecame captured to a second location aboard a waterborne vessel.